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1. Standoff and Point Detection of Thin Polymer Layers Using Microcantilever Photothermal Spectroscopy

   https://doi.org/10.1149/1945-7111/ac5657  

   Zhao, Yaoli; Chakraborty, Patatri; Stavinski, Nicholas; Velarde, Luis; Maheshkar, Vaishali; Dantu, Karthik; Phani, Arindam; Kim, Seonghwan; Thundat, Thomas (March 2022, Journal of The Electrochemical Society)

   Standoff detection based on optical spectroscopy is an attractive method for identifying materials at a distance with very high molecular selectivity. Standoff spectroscopy can be exploited in demanding practical applications such as sorting plastics for recycling. Here, we demonstrate selective and sensitive standoff detection of polymer films using bi-material cantilever-based photothermal spectroscopy. We demonstrate that the selectivity of the technique is sufficient to discriminate various polymers. We also demonstrate in situ, point detection of thin layers of polymers deposited on bi-material cantilevers using photothermal spectroscopy. Comparison of the standoff spectra with those obtained by point detection, FTIR, and FTIR-ATR show relative broadening of peaks. Exposure of polymers to UV radiation (365 nm) reveal that the spectral peaks do not change with exposure time, but results in peak broadening with an overall increase in the background cantilever response. The sensitivity of the technique can be further improved by optimizing the thermal sensitivity of the bi-material cantilever and by increasing the number of photons impinging on the cantilever. 

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2. Influence of thermal diffusion on the spatial resolution of photothermal microscopy

   https://doi.org/10.1117/12.2607795  

   Brown, Brendan S.; Hartland, Gregory V. (March 2022, Proc. SPIE 11990, Nanoscale and Quantum Materials: From Synthesis and Laser Processing to Applications)

   Kabashin, Andrei V.; Farsari, Maria; Mahjouri-Samani, Masoud (Ed.)

   Photothermal microscopy is a powerful method for investigating biological systems and solid state materials. Using a modulated pump to excite the sample, a continuous probe beam monitors the change in the refractive index of the sample due to the modulated heating. These experiments are typically performed at high frequencies to reduce the 1/f noise, achieving a higher signal to noise ratio. In this paper, we explore how the resolution and sensitivity of the photothermal experiments change when the modulation frequency is brought down below 100kHz. In the instance that the pump and probe are cofocused at the sample, the resolution is determined by the size of the pump beam. On the other hand, when a widefield pump is used, significant broadening occurs for frequencies under 20kHz. This broadening is attributed to thermal diffusion. However, the amount of broadening is less than that expected from the thermal diffusion length, which is about 1.7μm at 10kHz for nanoparticles in glycerol. We also explore the situation where the point spread functions of the pump and probe beams are smaller than the particle size as well as how the penetration depth depends on the properties of the pump and probe beams. 

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3. Nanoscale imaging of Gilbert damping using signal amplitude mapping

   https://doi.org/10.1063/5.0023455  

   Wu, Guanzhong; Cheng, Yang; Guo, Side; Yang, Fengyuan; Pelekhov, Denis V; Hammel, P Chris (January 2021, Applied Physics Letters)

   Ferromagnetic resonance force microscopy (FMRFM) is a powerful scanned probe technique that uses sub-micrometer-scale, spatially localized standing spin wave modes (LMs) to perform local ferromagnetic resonance (FMR) measurements. Here, we show the spatially resolved imaging of Gilbert damping in a ferromagnetic material (FM) using FMRFM. Typically damping is measured from the FMR linewidth. We demonstrate an approach to image the spatial variation of Gilbert damping utilizing the LM resonance peak height to measure the LM resonance cone angle. This approach enables determination of damping through field-swept FMRFM at a single excitation frequency. The extreme force sensitivity of ∼2 fN at room temperature can resolve changes of Gilbert damping as small as ∼2×10−4 at 2 GHz, corresponding to ∼0.16 Oe in FMR linewidth resolution. This high sensitivity, high spatial resolution, and single frequency imaging of Gilbert damping creates the opportunity to study spin interactions at the interface between an insulating FM and a small volume of nonmagnetic material such as atomically thin two-dimensional materials. 

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4. Principle and applications of peak force infrared microscopy

   https://doi.org/10.1039/D2CS00096B  

   Wang, Le; Wang, Haomin; Xu, Xiaoji G. (July 2022, Chemical Society Reviews)

   Peak force infrared (PFIR) microscopy is an emerging atomic force microscopy (AFM)-based infrared microscopy that bypasses Abbe's diffraction limit on spatial resolution. The PFIR microscopy utilizes a nanoscopically sharp AFM tip to mechanically detect the tip-enhanced infrared photothermal response of the sample in the time domain. The time-gated mechanical signals of cantilever deflections transduce the infrared absorption of the sample, delivering infrared imaging and spectroscopy capability at sub 10 nm spatial resolution. Both the infrared absorption response and mechanical properties of the sample are obtained in parallel while preserving the surface integrity of the sample. This review describes the constructions of the PFIR microscope and several variations, including multiple-pulse excitation, total internal reflection geometry, dual-color configuration, liquid-phase operations, and integrations with simultaneous surface potential measurement. Representative applications of PFIR microscopy are also included in this review. In the outlook section, we lay out several future directions of innovations in PFIR microscopy and applications in chemical and material research. 

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5. Exploring the Feasibility of a Thermoacoustic Metastructure for Energy Harvesting and Noise Mitigation

   https://doi.org/10.1121/2.0001670  

   Biswas, Samarjith; Manimala, James M. (December 2022, Proceedings of meetings on acoustics)

   The thermoacoustic effect provides a means to convert acoustic energy to heat and vice versa without the need for moving parts. This could enable the realization of mechanically-robust, noise mitigating energy harvesters via the development of thermoacoustic metastructures using additive and hybrid fabrication processes and materials. The mechanical, thermal and geometric properties of the porous stack that forms a set of acoustic waveguides in thermoacoustic metastructures are key to their performance. In this proof-ofconcept study, firstly, various ceramic and polymeric stack designs are evaluated using a custom-built thermoacoustic test rig. Influence of stack parameters such as material, length, location, porosity and pore geometry are correlated to simulations using DeltaEC, a software tool based on Rott’s linear approximation. Preliminary results also show a reduction in sound pressure level of around 5.28 dB across the thermoacoustic metastructure at resonance (117.5 Hz). An acousto-thermo-electric transduction scheme is employed to harvest useable electrical power using the best performing stack. Steady-state peak voltage generated was 33 mV for a temperature difference of about 30 degree Celsius across the stack at resonance. Further investigations are underway to establish structure-performance relationships by extracting scaling laws for power-to-volume ratio and frequency-thermal gradient dependencies. 

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